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Advancements in the AMDAR Humidity Sensing August 31, 2010

Advancements in the AMDAR Humidity Sensing August 31, 2010. A ircraft M eteorological Da ta R elay Pressure, Temperature, Wind + Humidity. Axel Hoff DWD (Deutscher Wetterdienst / German Meteorological Service). Background AMDAR Data Coverage. Wind and Temperature. >250,000 obs /day.

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Advancements in the AMDAR Humidity Sensing August 31, 2010

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  1. Advancements in the • AMDAR Humidity Sensing • August 31, 2010 Aircraft Meteorological Data Relay Pressure, Temperature, Wind+ Humidity Axel Hoff DWD (Deutscher Wetterdienst / German Meteorological Service)

  2. BackgroundAMDAR Data Coverage Wind and Temperature >250,000 obs /day … and now Humidity ~11,000 obs /day

  3. Background • Humidity sensor’s name: WVSS-II • Manufacturer: SpectraSensors Inc. (SSI), USAproducts: gas sensors for pipelines, rafineries, etc. • Physical Principle: Infrared Absorption Spectroscopy “2f – Method” by use ofTunable Diode Laser (TDL) SEB (System Electronics Box) Hoses for Inflow / Outflow Air Sampler Aircraft Skin Sampling Tube 23 cm SEB SEB

  4. Engineering System Electronics Box (SEB) 3-D Schematic • Infrared Tunable Diode Laser (TDL) scans a water vapor absorption band near 1.37 µm • Path length: 23 cm • Samples internally at 4 Hz • Generates every 2 seconds a “product”: water vapor mass mixing ratio

  5. Engineering History of the WVSS-II • Alpha Version 1: 2005 • First deployment on commercial aircraft • Issues indicated by testing: • condensation during descent • Coding algorithms limitations • Beta Version 2: 2006 • Implemented heated hose • New coding algorithm to capture precision and dynamic range of mixing ratio (10 - 40,000 ppmv) • Issues: • Moisture intrusion into sample chamber • Thermal stability of chamber of limiting accuracy • Production Version 3: 2008 • Improved laser seal • Improved thermal stability • Improved factory testing, calibration procedures

  6. AssessmentsNOAA Chamber Results Chamber Tests Against Reference Sensors (Chilled Mirror/RH373 and TS4500) • Sterling Field Support Center, October 2009: “WVSS-II sensor performed well under most of the test conditions” 0.037 g/kg 13.5 g/kg

  7. AssessmentsDWD Climate Chamber Results Reference Sensors: Chilled Mirrors MBW 373 and Toros From DWD Report, Sept 2009 The sensitivity of the WVSS-II touches the upper Troposphere.

  8. Assessments Climate Chamber Results of Research Centre Jülich, Germany Sensitivity limit at 0.02 g/kg (30 ppmv)Altitude: 200 hPaTemperat.: – 60 °C

  9. Assessments Radiosonde Field Tests Rockford, IL, (KRFD) Airport University of Wisconsin AERIBAGO / RS92 Tests November 2009, May 2010, and August 2010 Inter-comparisons of WVSS-II sensors show high correlation

  10. AssessmentsGPS-Met IPW Inter-Comparisons GPS-Met vs WVSS-II IPW Integrated Precipitatble Water (IPW) derived from GPS-Met and WVSS-II “After removing outlier points, slope of fit linear line is 1.0, with a 3% negative bias for WVSS-II v3 as compared with GPS-Met IPW.” (Seth Gutman) 8 Aircraft with WVSS-II v3 installed since November 1, 2009 Ascent/Descent through 500 hPa, ~95 IPW Pairs

  11. AssessmentsASOS Inter-Comparisons Louisville (KSDF) ASOS / WVSSII Surface / Lowest Level Sounding “When the temperature error components are removed, the moisture errors account for an RH error of <4%” (Ralph Petersen)

  12. Deployments Supplemental Type Certificates (STCs) issued by the FAA Completed for WVSSII: • August 26, 2009 for Boeing B757-200 (UPS fleet). • December 9, 2009 for Boeing B737-300 (SWA fleet). Planned: • STC for B737-700 is estimated to be awarded in December 2010. Current WVSS-II installations: • 25 sensors on United Parcel Service (UPS) on B757-200 aircraft • 5 sensors on Southwest Airlines (SWA) on B737-300 aircraft • 3 sensors on Lufthansa on Airbus A319 aircraft

  13. Deployments B757-300 STC B737-300 STC B737-700 STC

  14. Deployments Mean Bias of all WVSS-II observations against the First Guess of the DWD global model GME

  15. Future Activities • USA-NOAA plans 92 total installations, mostly on SWA B737-700 aircraft (2011) • EUMETNET-AMDAR plans for Airbus A320 family► replacement of the 3 old units ► 6 new deployments (2011 – 2012)► with potential for another 6 units (2012 +) • Research Aircraft Inter-comparisons:► BAe146 (UK Met Office) (2010)► Piper Navaho (NOAA) (2011) • Improved Coding and Metadata • Enhanced Monitoring • Extended Performance (to 1 ppmv, below 0.001 g/kg)

  16. Summary • WVSS-II meets or exceeds performance requirements from 50-40,000 ppmv. • WVSS-II moisture observations are as good or better than existing in situ observations. • WVSS-II has shown a degradation of performance at ppmv less than 50 (0.03 g/kg), which occurs ~1% of time at elevations above 30,000 ft AGL, in chamber tests, and in model inter-comparisons. • Follow-on research and development is planned to use TDL to observe water vapor down to 1 ppmv (0.0006 g/kg), and other trace gases.

  17. Thank you for your attention! Axel Hoffe-mail: axel.hoff@dwd.de

  18. Paper Contacts: • David Helms • Office of Science and Technology (W/OST12), National Weather Service • National Oceanographic and Atmospheric Administration • 1315 East-West Highway, Silver Spring, Maryland 20910 • Phone: 301-713-3557x193, Fax: 301-713-1253, E-mail: david.helms@noaa.gov • Axel Hoff • Deutscher Wetterdienst / German Meteorological Service • Dep. Observing Networks and Data • Div. Measurement Technology, TI 22 • Frankfurter Str. 135, 63067 Offenbach a. M., Germany • Phone: ++49 +69 -8062 -2852, Fax: ++49 +69 8062 -3827, E-mail: axel.hoff@dwd.de • Herman G.J. Smit • Forschungszentrum Jülich / Research Centre Juelich • Institute for Chemistry and Dynamics of the Geosphere ICG-2: Troposphere • 52425 Jülich, Germany • Phone: ++49 +2461 61 -3290, Fax: ++49 +2461 61 -5346, E-mail: h.smit@fz-juelich.de • Stewart Taylor • EUCOS/E-AMDAR Technical Coordinator • UKMet Office • Unit 4 Holland Business Park, Spa Lane, Lathom, L40 6LN • Phone: +44 (0)1695 558071, Fax: +44 (0)1392 885681, • E-mail: stewart.taylor@metoffice.gov.uk • Stig Carlberg • EUCOS/E-AMDAR Program Manager • Swedish Meteorological and Hydrological Institute • Sven Källfelts gata 15, SE-426 71, Vastra Frolunda, SWEDEN • Phone: +46 31 751 8976, E-mail: stig.carlberg@smhi.se • Michael Berechree • AMDAR Technical Coordinator • World Meteorological Organization

  19. WVSS-II NOAA Contract Performance Criteria

  20. Terms • WMO Aircraft Meteorological DAat and Reporting (AMDAR) Program: An international effort within the World Meteorological Organization (WMO) to coordinate the collection o f environmental observations from commercial aircraft. AMDAR largely leverages sensors (temperature and wind) and communication capabilities used to operate larger commercial aircraft for environmental applications. • E-AMDAR: A EUMETNET-AMDAR (E-AMDAR) Programme serves EUCOS requirements for additional upper air measurements of wind and temperature and to maximize the efficiency/cost ratio of implementing AMDAR (Aircraft Meteorological Data Relay) systems for EUMETNET Participants by reducing duplication in the use of resources and seeking to meet requirements in the most cost-effective manner. • U.S. AMDAR Program: A private/public partnership facilitating the collection of atmospheric measurements from commercial aircraft to improve aviation safety. This partnership includes seven air carriers, two federal agencies, and several private sector companies. • Aircraft Communications Addressing and Reporting System (ACARS): A digital datalink system, provided by ARINC and SITA, for transmission of short, relatively simple messages between aircraft and ground stations via radio or satellite. ACARS is also a message format transmitted to the ground using ARINC 620 protocol. • Meteorological Data Collection and Reporting System (MDCRS):The environmental component of the ACARS message. ARINC is under contract by the FAA and NWS to strip out the weather data from the ACARS messages and encoded these data into WMO compliant BUFR files using the ARINC “MDCRS” server in Annapolis, Maryland. The MDCRS BUFR file is NOAA’s operational contribution to the WMO AMDAR Program, transmitted via GTS. • Tropospheric Airborne Data DAta Reporting (TAMDAR): NASA Langley developed the TAMDAR sensor suite and communications capability (Iridium) to augment regional aircraft which typically do not have air-to-ground communications or high-quality sensors. Through TAMDAR, the number of airports which sounding data are collected from can be increased by significantly. NASA transferred the TAMDAR Program to a company called AirDat which provides TAMDAR data through a contract to NOAA.

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